Vortex-induced Vibration Power Generation Device With Magnetic Boundary Structure

ABSTRACT

A vortex-induced vibration power generation device with a magnetic boundary structure, including upper and lower opposite groups of fixed sleeves. Each fixed sleeve includes two vertical sleeves. The vertical sleeves are hollow cavities, and include sealed ends and open ends. Rotating magnetic poles are arranged in the sealed ends of the vertical sleeves. Coil slots are formed in the inner walls of the vertical sleeves. Coil windings are mounted in the coil slots. The vortex-induced vibration power generation device further includes linear bearings. The end portions of the linear bearings are fixedly connected with the open ends of the vertical sleeves through flanges. A vibration mechanism includes a vibration rod and vibration guide rods fixedly connected with the vibration rod. Magnetic coil mounting slots and anti-falling rings are arranged on the vibration guide rods. Magnetic coils are mounted in the magnetic coil mounting slots.

TECHNICAL FIELD

The present invention relates to a vortex-induced vibration power generation device with magnetic boundary structure which can be conversion with motion amplitude. The power generation device performs vortex-induced vibration to generate power by using ocean current energy, which belongs to the technical field of power generation devices.

BACKGROUND ART

With the continuous exploitation and consumption of earth resources, energy and resources on the land are on the decrease, and human demands for resources have turned to the ocean. Ocean resources not only include natural resources such as petroleum from the seabed, but also include energy contained in ocean itself, which is also a great treasure. Due to the continuous influence of tide and monsoon, ocean current energy and tidal energy become the most readily available and sustainable and available energy in ocean energy.

Vortex-induced vibration is a common vibration phenomenon in nature. When fluid (air, water) passes through a blunt structure, lift force changes due to trailing vortex shedding and causes reciprocating motion of the blunt structure. Since the vortex-induced vibration absorbs the kinetic energy of the fluid and converts this kinetic energy into energy that destroys the structure, it is usually a destructive phenomenon. However, if the vibration energy can be effectively converted into electrical energy, its potential energy will be immeasurable.

A conventional vortex-induced vibration power generation device is usually that two ends of a vibration rod are connected by springs. In a long-term vibration process of such a vibration boundary, the springs are relatively low in reliability, and bumps are inevitable during the vibration. Once anti-corrosion layers of the springs are destroyed, rapid rusting will occur under a seawater environment and destroy the performance of the springs. Therefore, it is necessary to develop a vortex-induced vibration power generation device having a magnetic boundary.

SUMMARY OF THE INVENTION

Objective: the present invention provides a vortex-induced vibration power generation device with magnetic boundary structure. The power generation device can overcome the defects of short service life and relatively low reliability of a spring boundary of a conventional vortex-induced vibration power generation device in a use process. By the adoption of the principle that magnets having like polarities repel each other, the vortex-induced vibration power generation device of the present invention provides damping of a vibration boundary as a boundary.

The power generation device of the present invention has the advantages of amplifying the amplitude and prolonging the service life, which converts vibration mechanical energy generated by seawater into relative motion between a coil winding and a magnetic coil to cut magnetic lines to generate electrical energy.

Summary: in order to solve the above technical problems, the technical solution adopted in the present invention is as follows:

a vortex-induced vibration power generation device with magnetic boundary structure, including upper and lower opposite groups of fixed sleeves, is proposed. Each fixed sleeve includes a horizontal connection rod and two vertical sleeves connected through the horizontal connection rod. The vertical sleeves are hollow cavities, and include sealed ends and open ends. Rotating magnetic poles are arranged in the sealed ends of the vertical sleeves. Coil slots are formed in the inner walls of the vertical sleeves. Coil windings are mounted in the coil slots. The vortex-induced vibration power generation device further includes linear bearings. The end portions of the linear bearings are fixedly connected with the open ends of the vertical sleeves through flanges. Guide rails are arranged in the linear bearings. The vortex-induced vibration power generation device further includes a vibration mechanism. The vibration mechanism includes a vibration rod and vibration guide rods fixedly connected with the vibration rod. The vibration guide rods consist of upper guide rods and lower guide rods. Magnetic coil mounting slots and anti-falling rings are arranged on the upper guide rods and the lower guide rods. Magnetic coils are mounted in the magnetic coil mounting slots. The end portions of the vibration guide rods are provided with movable magnetic poles, and are also provided with shift fork structures for driving the rotating magnetic poles to rotate. The upper guide rods and the lower guide rods of the vibration guide rods respectively extend into the upper and lower opposite groups of fixed sleeves.

The rotating magnetic poles include rotating shafts. Springs are arranged on the rotating shafts in a sleeving manner. One end of each spring is fixedly connected with the side wall of a cavity in each vertical sleeve, and the other end of the spring is fixedly connected with each rotating magnetic pole. The rotating magnetic poles are provided with deflector rods on the outer circumferences of the rotating shafts.

Further, four deflector rods are provided, and are equidistantly and annularly arranged on the outer circumferences of the rotating shafts.

The vortex-induced vibration power generation device further includes a base and racks. The racks include stand bars and sleeves fixed on the stand bars. The stand bars are fixedly welded on the base, and the sleeves are fixedly arranged on the upper fixed sleeve in a sleeving manner.

The linear bearings are cylindrical, in which a plurality of grooves are formed. Balls are mounted in the grooves. Y-shaped sealing rings are arranged at openings of the linear bearings.

The outer diameters of the anti-falling rings on the vibration guide rods are consistent with the inner diameters of the vertical sleeves. The outer diameters of the anti-falling rings and the inner diameters of the vertical sleeves are both greater than the inner diameters of the linear bearings. In case of vibration, the linear bearings are fixedly connected with the fixed sleeves through the flanges, and the vibration guide rods may not fall off from the fixed sleeves in the presence of the linear bearings.

Compared with the prior art, the technical solution of the present invention has the following beneficial effects.

Firstly, a vibration frequency of the vortex-induced vibration power generation device is at a stable value for a long time, and the device is located in a seawater corrosion environment for a long time, so that the magnetic boundary is higher in reliability and longer in service life than that in traditional spring boundary.

Secondly, most energy is consumed by springs of the traditional spring boundary in a vibration process. For example, in downward vibration, the pressed reactive force of the lower spring needs to be resisted, and the pulled reactive force of the upper spring needs to be born.

However, the magnetic boundary is on the contrary. After upward motion, the magnetic boundary provides one downward acting force which pushes the vibration rod to move downwards, so that greater motion amplitude may be generated, and thus an effect of amplifying the vibration energy is achieved.

Thirdly, the device of the present invention may provide a repulsive force through cooperation between shift forks and the rotating magnetic poles, and also provide an upward attractive force by changing rotating phases of the rotating magnetic poles.

Finally, the present invention would replace the vibration rods, the magnetic poles and vibration distances of the vibration guide rods according to the condition of an actual water area, and is high in environmental adaptability.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic structural diagram of a device of the present invention;

FIG. 2 is a structural exploded diagram of a device of the present invention;

FIG. 3 is a schematic structural diagram of a vibration rod of the present invention;

FIG. 4 is a schematic structural diagram of a vibration guide rod of the present invention;

FIG. 5 is a schematic structural diagram of a magnetic coil of the present invention;

FIG. 6 is a schematic structural diagram of a movable magnetic pole of the present invention;

FIG. 7 is a schematic structural diagram of a vibration guide rod connected with a movable magnetic pole and a shift fork structure of the present invention;

FIG. 8 is a schematic structural diagram of a shift fork of the present invention;

FIG. 9 is a schematic structural diagram of a fixed sleeve of the present invention;

FIG. 10 is a schematic structural diagram of a coil winding of the present invention;

FIG. 11 is a schematic structural diagram of a magnetic pole cover of the present invention;

FIG. 12 is a schematic structural diagram of a movable magnetic pole of the present invention;

FIG. 13 is a schematic structural diagram of a linear bearing of the present invention;

FIG. 14 is a schematic structural diagram of a fixed rack of the present invention; and

FIG. 15 is a schematic diagram illustrating that a shift fork drives a deflector rod to move of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The technical solution of the present invention is further described below with reference to specific embodiments.

As shown in FIGS. 1 to 15, a vortex-induced vibration power generation device with a magnetic boundary structure of the present invention includes upper and lower opposite groups of fixed sleeves 3. Each fixed sleeve 3 includes a horizontal connection rod 32 and two vertical sleeves 31 connected through the horizontal connection rod 32. The vertical sleeves 31 are hollow cavities, and include sealed ends and open ends. Rotating magnetic poles 38 are arranged in the sealed ends 35 of the vertical sleeves 31. Connection flanges 33 are arranged at the open ends of the vertical sleeves 31. Sealing covers 37 are arranged outside the sealed ends 35, and are used for sealing the sealed ends 35. Coil slots 34 are formed in the inner walls of the vertical sleeves 31. Coil windings 36 are mounted in the coil slots 34. The device of the present invention further includes linear bearings 4. One end portion of each linear bearing 4 is provided with a flange 41. The linear bearings 4 are fixedly connected with the open ends of the vertical sleeves 31 through flanges (fixedly connected with the connection flanges 33 through the flanges 41). The linear bearings 4 are cylindrical, with flange structures at the bottoms of the round sleeves and axial motion forms on the inner sides. Guide rails 42 are arranged in the linear bearings 4. A plurality of grooves is also formed in the linear bearings 4. Balls 43 are mounted in the grooves. A Y-shaped sealing ring is arranged at the other end portion (the opening) of each linear bearing 4. The linear bearings 4 are used for limiting longitudinal motions of vibration guide rods 2 in the fixed sleeves 3 (in the cavities of the vertical sleeves 31), namely the guide rails 42 limit the longitudinal motions of the vibration guide rods 2, and the balls 43 are used for reducing dry friction generated by vibration. The device of the present invention further includes a vibration mechanism. The vibration mechanism includes a vibration rod 1 and the vibration guide rods 2 fixedly connected with the vibration rod 1. The vibration guide rods 2 include guide rods 22 divided into upper guide rods and lower guide rods. Magnetic coil mounting slots 25 and anti-falling rings 24 are arranged on the upper guide rods and the lower guide rods. Magnetic coils 86 are mounted in the magnetic coil mounting slots 25. The end portions of the upper guide rods and the lower guide rods are respectively provided with movable magnetic poles 87, and also provided with shift fork structures 27 for driving the rotating magnetic poles 38 to rotate. The shift fork structures 27 are fixed at two end portions of the vibration guide rods 2 through fixing rings 26. The upper guide rods and the lower guide rods of the vibration guide rods 2 respectively extend into the upper and lower opposite groups of fixed sleeves 3.

The rotating magnetic poles 38 include rotating shafts 310. Springs are arranged on the rotating shafts 310 in a sleeving manner. One end of each spring is fixedly connected with the side wall of the cavity in each vertical sleeve 31, and the other end of the spring is fixedly connected with each rotating magnetic pole 38. The rotating magnetic poles 38 are fixedly connected with the vertical sleeves 31 through the springs. The rotating magnetic poles 38 are provided with four deflector rods 39 along the outer circumferences of the rotating shafts 310, and the four deflector rods 39 are equidistantly and annularly arranged on the outer circumferences of the rotating shafts 310. Three to four semicircular groove structures matched with the deflector rods 39 are arranged on the shift fork structures 27. The shift fork structures 27 may push the rotating magnetic poles 38 to rotate along the rotating shafts 310 through the cooperative connection with the deflector rods 39 when moving upwards with the vibration guide rods 2 along a longitudinal direction. After the shift fork structures 27 move downwards with the vibration guide rods 2, the rotating magnetic poles 38 rotate to original positions under the action of the springs, and at this time, the rotating magnetic poles 38 are opposite to the movable magnetic poles 87 by different polarities again.

The vortex-induced vibration power generation device with the magnetic boundary structure of the present invention further includes a base 6 and racks 5. The racks 5 include stand bars 52 and sleeves 51 fixed on the stand bars 52. The stand bars 52 are fixedly welded on the base 6, and the sleeves 51 are fixedly arranged on the upper fixed sleeve 3 in a sleeving manner. Through welding fixing, the end portions of the two vertical sleeves 31 of the lower fixed sleeve 3 are fixed on the base 6. The base 6 is settled down to fix the whole power generation device.

The vibration rod 1 is matched with mounting holes 21 on the vibration guide rods 2 through fixing holes 12 in two ends, and then is fixedly connected through bolt holes 23 on the vibration guide rods 2 (i.e., the fixing holes 12 extend into the mounting holes 21, and bolts pass through the bolt holes 23 and the fixing holes 12 to fixedly connect the vibration rod 1 with the vibration guide rods 2). The vibration guide rods 2 include the guide rods 22 divided into the upper guide rods and the lower guide rods. The magnetic coil mounting slots 25 and the anti-falling rings 24 are arranged on the upper guide rods and the lower guide rods. The outer diameters of the anti-falling rings 24 are consistent with the inner diameters of the vertical sleeves 31 of the fixed sleeves 3, and are greater than the inner diameters of the guide rails 42 of the linear bearings 4, so that the vibration guide rods 2 may not get rid of the limitation from the linear bearings 4 during the longitudinal up-and-down movement. The magnetic coils 86 are mounted at the magnetic coil mounting slots 25. The movable magnetic poles 87 are mounted at two head end portions of the vibration guide rods 2 through mutually cooperative connection of internal and external threads, and the shift fork structures 27 are also fixed at the two end portions of the vibration guide rods 2 respectively through the fixing rings 26. The outer diameters of the anti-falling rings 24 on the vibration guide rods 2 are consistent with the inner diameters of the vertical sleeves 31, and the outer diameters of the anti-falling rings 24 and the inner diameters of the vertical sleeves 31 are both greater than the inner diameters of the linear bearings 4. In case of vibration, the linear bearings 4 are fixedly connected with the fixed sleeves 3 through the flanges, and the vibration guide rods 2 will not fall off from the fixed sleeves 3 in the presence of the linear bearings 4. The number of the coil windings 36 is several times of that of the magnetic coils 86, so as to ensure that the vibration guide rods 2 continuously cut magnetic lines when driving the magnetic coils 86 to vibrate up and down relative to the coil windings 36. Currents generated by the magnetic line cutting motion generated by the relative motion are concentrated through circuits and stored.

As shown in FIG. 15 illustrating a schematic motion diagram of the shift fork structures 27 and the rotating magnetic poles 38 in a motion process, the direction from left to right indicates that the shift fork structures 27 move upwards and drive the rotating magnetic poles 38 to rotate 180 degrees along the rotating shafts 310.

The power generation device of the present invention is placed in a corresponding water area. When there is water passing by, the vibration rod 1 may vibrate up and down by vortex-induced vibration to drive the vibration guide rods 2 fixedly connected therewith to vibrate up and down. The vibration guide rods 2 drive the magnetic coils 86 to do reciprocating motion in the cavities of the vertical sleeves 31 of the fixed sleeves 3. A large number of coil windings 36 are mounted in the coil slots 34 of the fixed sleeves 3. When the magnetic coils 86 and the coil windings 36 do the reciprocating motion, currents may be generated. That is, the vibration rod 1 moves relative to the fixed sleeves 3 when driving the vibration guide rods 2 to move, and a power generation form implemented by the relative motion between the arrayed magnetic coils 86 and coil windings 36 is used to convert vibration mechanical energy into electrical energy.

When the vibration guide rods 2 move upwards to the tops of the vertical sleeves 31, the movable magnetic poles 87 and the rotating magnetic poles 38 are opposite by different polarities and attract each other, and the attractive force accelerates the upward motion of the vibration guide rods 2. The shift fork structures 27 mounted at the end portions of the vibration guide rods 2 push the deflector rods 39 on the rotating magnetic poles 38, so as to drive the rotating magnetic poles 38 to rotate along the rotating shafts 310. After the rotating magnetic poles 38 rotate 180 degrees, the rotated rotating magnetic poles 38 and the movable magnetic poles 87 are opposite by the same polarities and repel each other. At this time, the rotating magnetic poles 38 push the vibration guide rods 2 to move downwards. After the shift fork structures 27 move downwards with the vibration guide rods 2, the rotating magnetic poles 38 rotate to the original positions under the action of reset springs, and at this time, the rotating magnetic poles 38 are opposite to the movable magnetic poles 87 by different polarities again, and so on and on. That is, after the shift fork structures 27 drive the rotating magnetic poles 38 to rotate, the rotating magnetic poles 38 may rotate to the original positions under the action of the springs. The vibration guide rods 2 continuously and stably do the reciprocating motion under the action of the continuous conversion of the attractive force and the repulsive force at the two ends and the vortex-induced force generated by ocean current energy.

The lengths of the shift fork structures 27 in the device of the present invention are adjusted according to a velocity change of the water area, so that a phase difference of early rotation of the rotating magnetic poles 38 may be changed, and then the strength of the repulsive force of the magnetic boundary is changed. A removal-facilitated structural form is used between the vibration rod 1 and the vibration guide rods 2, so that fast removal and replacement may be realized according to factors such as a mean velocity and a density of an installation environment. The vibration rod 1 moves relative to the fixed sleeves 3 when driving the vibration guide rods 2 to move, and the power generation form implemented by the relative motion between the arrayed magnetic coils 86 and coil windings 36 is used to convert the vibration mechanical energy into the electrical energy.

The power generation device of the present invention is installed at the seabed or the bottom of a riverway or in a water area having a certain velocity, and the installation direction that an axial direction of the vibration guide rods is perpendicular to an incoming direction should be ensured. Energy of water having a certain velocity is converted into mechanical energy and then into electrical energy. The racks 5 and the base 6 should be made of materials resistant to seawater corrosion or have corrosion resistant surfaces. The movable magnetic poles 87 and the rotating magnetic poles 38 in the device are permanently magnetic.

In the present invention, the outer diameter and weight of the vibration rod may be determined according to the mean velocity of the actual water area. The damping of the vibration boundary may be changed by changing the magnetic fluxes of the fixed magnetic poles and the movable magnetic poles. The sizes and installation distances of the movable magnetic poles may be changed according to the maximum amplitude of the vibration rod. An early rotation amount of the rotating magnetic poles 38 during the upward motion of the vibration guide rods 2 may be changed by changing the lengths of the shift fork structures 27, and then the attractive force when the different polarities are opposite is changed.

The device has the characteristics of convenience in installation, high adaptability, high reliability, long service life and the like, is clean and pollution-free and may be clustered in a related water area, so that currents generated by a plurality of devices are processed and stored uniformly. 

What is claimed is:
 1. A vortex-induced vibration power generation device with magnetic boundary structure, comprising upper and lower opposite groups of fixed sleeves, where each fixed sleeve comprises a horizontal connection rod and two vertical sleeves connected through the horizontal connection rod; the vertical sleeves are hollow cavities, and comprise sealed ends and open ends; rotating magnetic poles are arranged in the sealed ends of the vertical sleeves; coil slots are formed in the inner walls of the vertical sleeves; coil windings are mounted in the coil slots; the vortex-induced vibration power generation device further comprises linear bearings; the end portions of the linear bearings are fixedly connected with the open ends of the vertical sleeves through flanges; guide rails are arranged in the linear bearings; the vortex-induced vibration power generation device further comprises a vibration mechanism; the vibration mechanism comprises a vibration rod and vibration guide rods fixedly connected with the vibration rod; the vibration guide rods consist of upper guide rods and lower guide rods; magnetic coil mounting slots and anti-falling rings are arranged on the upper guide rods and the lower guide rods; magnetic coils are mounted in the magnetic coil mounting slots; the end portions of the vibration guide rods are provided with movable magnetic poles, and are also provided with shift fork structures for driving the rotating magnetic poles to rotate; and the upper guide rods and the lower guide rods of the vibration guide rods respectively extend into the upper and lower opposite groups of fixed sleeves.
 2. The vortex-induced vibration power generation device with the magnetic boundary structure according to claim 1, wherein the rotating magnetic poles comprise rotating shafts; springs are arranged on the rotating shafts in a sleeving manner; one end of each spring is fixedly connected with the side wall of a cavity in each vertical sleeve, and the other end of the spring is fixedly connected with each rotating magnetic pole; and the rotating magnetic poles are provided with deflector rods on the outer circumferences of the rotating shafts.
 3. The vortex-induced vibration power generation device with the magnetic boundary structure according to claim 2, wherein four deflector rods are provided, and are equidistantly and annularly arranged on the outer circumferences of the rotating shafts.
 4. The vortex-induced vibration power generation device with the magnetic boundary according to claim 1, further comprising a base and racks, wherein the racks comprise stand bars and sleeves fixed on the stand bars; the stand bars are fixed on the base, and the sleeves are fixedly arranged on the upper fixed sleeve in a sleeving manner.
 5. The vortex-induced vibration power generation device with the magnetic boundary according to claim 1, wherein the linear bearings are cylindrical, in which a plurality of grooves are formed; balls are mounted in the grooves; and Y-shaped sealing rings are arranged at openings of the linear bearings.
 6. The vortex-induced vibration power generation device with the magnetic boundary according to claim 1, wherein the outer diameters of the anti-falling rings on the vibration guide rods are consistent with the inner diameters of the vertical sleeves; the outer diameters of the anti-falling rings and the inner diameters of the vertical sleeves are both greater than the inner diameters of the linear bearings.
 7. The vortex-induced vibration power generation device with the magnetic boundary according to claim 1, wherein the vibration rod consists of a horizontal portion and bent portions located at the end portions of the horizontal portion. 